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Neutrinos andNeutrinos andthe large scale structurethe large scale structure
Lauro MoscardiniLauro MoscardiniDip. Astronomia,Università di Bologna, ItalyDip. Astronomia,Università di Bologna, Italy
[email protected]@unibo.it
Perspectives in Neutrino Physics & AstrophysicsPerspectives in Neutrino Physics & AstrophysicsBologna, 17th June 2005Bologna, 17th June 2005
• the role of neutrinos in the cosmic budgetthe role of neutrinos in the cosmic budget• neutrinos and the formation of cosmic structuresneutrinos and the formation of cosmic structures• cosmological constraints on the neutrino masscosmological constraints on the neutrino mass
Independent data sets give a consistent determination of the amount of Dark Energy and Dark Matter in the Universe. The relative weights being measured by their density parameter
ii= = ii / / cc
where c = 10-29 g/cm3 is the critical density i.e. the energy density which closes the Universe
The cosmic budgetThe cosmic budget
The cosmicThe cosmic budget budget
About 73% of the energy content of our Universe is in the form
of some exotic component, called Dark Energy, or “Quintessence”, which causes a large-scale cosmic repulsion among celestial objects, thereby mimicking a sort of anti-gravity effect. The simplest dark energy candidate is the Cosmological Constant .
Only about 4% of the cosmic energy budget is in the form of ordinary “baryonic” matter, out of which only a small fraction shines in the galaxies (quite likely most of the baryon reside in filaments forming the Warm-Hot Intergalactic Medium (WHIM), a sort of cosmic web connecting the galaxies and clusters of galaxies).
About 23% of the cosmic budget is made of Dark Matter, a collisionless component whose presence we only perceive gravitationally.
Cosmological neutrinosCosmological neutrinos
Neutrinos are in equilibriun with the primeval plasma through weak interaction reactions. They decoupledecouple from the plasma at TTdecdec 1 MeV 1 MeVToday we have a cosmological neutrino background at a temperaturetemperatureTT=(4/11)=(4/11)1/31/3 T T 1.945 K, 1.945 K, corresponding to kT1.68•10–4 eV
The Neutrino densityThe Neutrino densityThis corresponds to a present neutrino number density ofnn00 0.1827 0.1827 ··TT
33 112 cm 112 cm-3-3
That for a massive neutrino translates in00 1.9 1.9 · · NN <m <m/10eV> /10eV> · · 1010–30–30 g cm g cm3 3
or equivalently00 h h22 0.1 0.1 · · NN <m <m/10eV> /10eV> i.e. in order to be a good candidate for the dark matter component of our universe (0M h20.14), neutrinos need to have a mean mass of approximately 5 eV!mean mass of approximately 5 eV!
A direct detection is very difficultdirect detection is very difficult but…They have a strong impact on the formation and evolution of formation and evolution of cosmic structures, cosmic structures, the so-called cosmic clustering, cosmic clustering, which now can be accurately measured.
The Model for Structure formationThe Model for Structure formation
The The cosmic microwave backgroundcosmic microwave background (CMB) (CMB) tells us that the universe is almost perfectly tells us that the universe is almost perfectly uniform spatially, with density variations uniform spatially, with density variations from place to place only at the level of from place to place only at the level of 1010-5-5.
WMAPWMAP
The Model for Structure formationThe Model for Structure formation
Gravitational instabilityGravitational instability caused these tiny fluctuations to grow in amplitude into the large scale structure we observe: gravity is an attactive force and tends to increase the overdensity over time
Redshift evolution of clusteringRedshift evolution of clustering
The linear solutionThe linear solutionIFIF all the matter contributing to the cosmic density is able to cluster (like dark matter or ordinary matter with negligible pressure), then density fluctuations grow as the cosmic expansion factor a (1+z)-1, i.e.
a,a, But, IF IF some fraction (1-*) is unable to cluster (i.e. it is gravitationally inert), then the growth will be slowerslower
aapp,, where p p **
0.60.6..Note that the inert component can include dark energy if present and photons and neutrinos on sufficiently large scales.
What about neutrinos?What about neutrinos?Massive non-relativistic neutrinos cannot cluster on small scales because of their high velocities. In the period between matter and dark energy domination, neutrinos are a roughly constant fraction f = (1-*) of the matter density. Then the net fluctuation growth factor is
(aDE/aMD)p 4700p 4700 exp(-4 f )Even a small neutrino fraction has a Even a small neutrino fraction has a large effect! large effect!
The transfer function T(k)The transfer function T(k)In cosmology this effect can be quantify by using the density density power spectrum P(K)power spectrum P(K), giving the variance of fluctuations in Fourier space. Usually this can be written as
P(k)=A kP(k)=A kn n TT22(k)(k)
Neutrino free streaming: Neutrino free streaming: P(k)/P(k)=-8fP(k)/P(k)=-8f
Practical consequencesPractical consequences There is a scale, called There is a scale, called neutrino free- neutrino free-
streaming scale,streaming scale, below wich clustering is below wich clustering is strongly suppressed.strongly suppressed.
Neutrinos will not cluster in overdense Neutrinos will not cluster in overdense clumps so small that their escape velocity is clumps so small that their escape velocity is much smaller than the typical neutrino much smaller than the typical neutrino velocity.velocity.
On larger scalesOn larger scales neutrinos behave just as neutrinos behave just as cold dark matter: cold dark matter: * =1 and p=1
The power spectrum changes its shape in The power spectrum changes its shape in a characteristic waya characteristic way
N-body resultsN-body results
There is There is less less clustering clustering in models in models with with massive massive neutrinosneutrinos
The top-down scenarioThe top-down scenario
Now we know that 0m0m 0.3. 0.3. If we assume that all dark matter is contributed by neutrinos, because of free-streaming there will be a strong suppression of power at small scales. Consequently cosmic structures would have formed first at large scales (galaxy clusters), and smaller structures (like galaxies) would form later by fragmentation: this is the so-called top-down scenariotop-down scenario
But, starting from late ’80s, we have evidences in favour of a bottom-upbottom-up structure formation (hierarchical) model, where objects formed first at small scale.
Now this is confirmed by observational data. A cold cold (i.e. non-relativistic when it decoupled from the thermal background) dark dark mattermatter (CDM) component is strongly favoured
dark matter dark matter cannot be cannot be dominated by dominated by neutrinos!neutrinos!
However, neutrinos, even if non-dominant, are massive and massive and abundantabundant. So, if we have accurate measuments of cosmic clustering (as we start to have now), we can hope to use cosmological observations to put constraints on the neutrino mass which can be combined with laboratory bounds
Weighing neutrinosWeighing neutrinos
Cosmological observablesCosmological observables Cosmic microwave background (CMB)Cosmic microwave background (CMB) Galaxy surveys & large scale structure (LSS)Galaxy surveys & large scale structure (LSS) Lyman alpha forestLyman alpha forest Galaxy clustersGalaxy clusters Gravitational lensingGravitational lensing ……
Tegmark
WMAP CMB WMAP CMB anisotropiesanisotropies
CMB alone is NOT sensitive CMB alone is NOT sensitive to massive neutrinos:to massive neutrinos: there is only a small enhancement of the acoustic peaks. However, they are able to put strong constraints on the matter density and on other parameters: this allows, when combined with other data, to break degeneraciesbreak degeneracies
Large surveys with Large surveys with >200k galaxy >200k galaxy redshifts: redshifts: 2dF and 2dF and SDSSSDSS
In linear regime, In linear regime, sensitive to neutrino sensitive to neutrino fraction ffraction f==//mm
GalaxyGalaxysurveyssurveys
SDSSSDSS
2dF vs SDSS Power spectra2dF vs SDSS Power spectra
50 Mpc/h
Pope et al. 2004Pope et al. 2004Tegmark et al. 2003Tegmark et al. 2003
80 % of the baryons at z=3 are in the Lyman- forest (Rauch 1998)
baryons as tracer of the dark matter density field
IGM ~ DM
at scales larger than the Jeans length ~ 1 com Mpc
Lyman-Lyman- forestforest
Viel et al. 2005
QSOQSO
obs.obs.
3D Lyman-alpha 3D Lyman-alpha Power SpectrumPower Spectrum
Run many Run many simulations with simulations with CDM-like 3D spectraCDM-like 3D spectra
Extract 1D Flux Extract 1D Flux power spectra from power spectra from each simulationeach simulation
Fit amplitude and Fit amplitude and slope of power at 1 slope of power at 1 MpcMpc
Very sensitive because at small small scales,scales, but quitemodel-dependent
Cmbgg OmOlCmbgg OmOl
Cmbgg OmOlCmbgg OmOl
Cmbgg OmOlCmbgg OmOlCMB
Cmbgg OmOlCmbgg OmOlCMB
+
LSS
Cmbgg OmOlCmbgg OmOlCMB
+
LSS
+
LyaF
Tegmark 2005Tegmark 2005
A partial summary ofA partial summary of neutrino mass from cosmology neutrino mass from cosmology
Data Authors mi
2dFGRS2dFGRS Elgaroy et al 2002Elgaroy et al 2002 <1.8 eV<1.8 eV
WMAP+2dF+..WMAP+2dF+.. Spergel et al. 2003Spergel et al. 2003 <0.7 eV<0.7 eV
WMAP+2dFWMAP+2dF Hannestad 2003Hannestad 2003 <1.0 eV<1.0 eV
SDSS+WMAPSDSS+WMAP Tegmark et al. 2004Tegmark et al. 2004 <1.7 eV<1.7 eV
WMAP+2dFWMAP+2dF Crotty et al. 2004Crotty et al. 2004 <1.0 eV<1.0 eV
WMAP+SDSS LyaWMAP+SDSS Lya Seljak et al. 2004Seljak et al. 2004 <0.43 eV<0.43 eV
Clusters+WMAPClusters+WMAP Allen et al. 2004Allen et al. 2004 0.56 0.56 +0.30+0.30–0.26–0.26 eV eV
All upper limits 95%, but different assumed priors!
ConclusionsConclusions
Cosmological constraints on neutrino mass Cosmological constraints on neutrino mass ((1eV 1eV total)total) arise from arise from power spectrumpower spectrum (but attention to (but attention to priors)priors)
Wide variety of techniques/experiments needed to Wide variety of techniques/experiments needed to eliminate eliminate systematics/degeneraciessystematics/degeneracies
Physicists must become familiar with: inflation, Physicists must become familiar with: inflation, CMB, LSS, dark energy, … CMB, LSS, dark energy, …
Future Galaxy Cluster Future Galaxy Cluster SurveysSurveys
LSST (Large Synoptic Survey Telescope)LSST (Large Synoptic Survey Telescope)
A proposed ground-based8.4-meter telescope detecting galaxy clusters by their weak lensing signals.
Sky coverage: 18000 deg2,Number of clusters: 200,000;
(0.1 < z < 1.4, Mmin=1013.7h-1Msun)
Future CMB SurveysFuture CMB SurveysPlanck SurveyorPlanck Surveyor
Constraints from clusters will be complementary to those from cosmic microwave background (CMB) anisotropy measurement.
Measurement of TT, EE and TE in three frequency bands.
Constraints from CMB (unlensed) alone (1σ):
eV;2.0)( m
e.g. Eisenstein, Hu & Tegmark (1999)
,0.1)( aw
(Σ mν) ~ 0.04 eV. (LSST + Planck)
Weak Gravitational LensingWeak Gravitational Lensing
Unlike galaxy surveys and Lyman alpha, lensingdirectly probes mass distribution!
Weak LensingWeak Lensing
Abazajian & Dodelson (2002)
•Measure power spectrum AND/OR measure growth of spectrum at late time• Sensitive to neutrino mass AND dark energy• Ergo, accelerator neutrino experiments will teach us about dark energy!
Mixed Dark Matter?Mixed Dark Matter? mm=1, =1, =0.2, =0.2, hh=0.45=0.45
* Consistent with 2dF.* Consistent with 2dF.* To fit WMAP,* To fit WMAP,a a break break is required in theis required in thePrimordial power-spectrumPrimordial power-spectrum(e.g. Blanchard et al. 2003).(e.g. Blanchard et al. 2003).
* Also at odds with HST’s H* Also at odds with HST’s H00,,
SNIa , cluster evolution andSNIa , cluster evolution andbaryon fraction.baryon fraction.
Elgaroy & Lahav, 2003Elgaroy & Lahav, 2003
P(k) 2dF P(k) 2dF
WMAPWMAP